KR19990024745A - Peripheral brightness correction device of the image projector - Google Patents

Abstract

The present invention relates to an apparatus for compensating brightness of a peripheral part of an image projector, wherein the horizontal and vertical parabola signals are synchronized with a synchronization signal synchronized with a blank period of an image signal, and applied to a variable gain amplifier for amplifying the input image signal. By correcting the signal, by detecting the magnitude of the beam current according to the size of the image signal and comparing it with the reference voltage, and according to the result by varying the degree of amplification of the image signal combined with the horizontal, vertical parabola wave in the variable gain amplifier In the bright screen, the correction is large, in the dark screen, the correction is small, and the overall uniform brightness can be viewed.

Description

Peripheral brightness correction device of the image projector

The present invention relates to an apparatus for compensating the brightness of a peripheral portion of an image projector, and in particular, to detect the magnitude of a beam current to determine the brightness of a screen, and to correct an image signal input according to the brightness of a screen with a parabola signal, The present invention relates to a peripheral brightness correction device of an image projector that detects a magnitude of a beam current and corrects brightness of a peripheral part of a screen by varying amplification degree of an image signal combined with horizontal and vertical parabola waveforms in a variable amplifier according to the result.

In general, TVs have different brightnesses in the center and peripheral areas of the screen even when the same video signal is input. This is caused by the difference in the distance that the beam current is reached. That is, since the center portion is close to the beam current reach distance and the periphery portion is far from the distance, the speed of the electron decreases toward the periphery and the brightness decreases.

This phenomenon is caused by the addition of a projection system in the image projector that magnifies the image through the lens, the difference in brightness between the center and the periphery is greater.

In other words, as shown in FIG. 1, there is a difference between the distance of the beam current from the projection system to the center of the screen and the distance of the periphery of the screen, and thus the horizontal brightness distribution and the vertical brightness distribution are shown on the screen where the final image is displayed. As you can see, the darker it gets to the periphery of the screen.

That is, when white unformity is measured, when all screens are white, the same brightness cannot be achieved, and the darker the color becomes, the darker it gets.

As described above, the conventional apparatus has a problem in that a brightness difference occurs on the screen on which the final image appears due to the difference between the reach distance of the beam current from the projection system to the center of the screen and the distance to the peripheral portion.

The purpose of the present invention is to correct the brightness of the peripheral portion by modulating the input image signal into a parabola signal in order to solve such a conventional problem by detecting the magnitude of the beam current, that is, the degree of correction according to the degree of brightness of the screen An object of the present invention is to provide a brightness compensator for a peripheral portion of an image projector that can view a screen of uniform brightness.

1 is a configuration diagram of a projection system in an image projector.

Figure 2 is a horizontal, vertical brightness distribution in Figure 1;

Figure 3 is an embodiment of the present invention.

4 and 5 are each sub-output waveform diagram in FIG.

Explanation of symbols for main parts of the drawings

100: correction unit 110: beam current detection unit

120: comparison unit 200: correction signal generation unit

210: synchronization signal generator 220: horizontal parabola signal generator

230: vertical parabolic signal generator 300: variable gain amplifier

400: image processing unit 500: image output unit

Peripheral brightness correction device of the image projector for achieving the object of the present invention detects the magnitude of the beam current according to the magnitude of the input image signal, and compares the detected output signal with the reference signal and outputs the corresponding signal according to the discrimination Means; Correction signal generating means for generating vertical and horizontal synchronization signals synchronized with a blank period of the video signal, outputting a horizontal parabola signal synchronized with a horizontal synchronous signal, and outputting a vertical parabola signal synchronized with a vertical synchronous signal; Variable gain amplifying means for adjusting the horizontal and vertical parabolic signals with a gain in accordance with an output signal of the correction judging means, and outputting the sum of the horizontal and vertical parabola signals; Image processing means for demodulating and outputting the output signal of the variable gain amplifying means; And an image output means for amplifying the output signal of the image processing means and outputting the amplified signal to the CRT.

Hereinafter, the operation and effects of the present invention will be described with reference to one embodiment.

3 is an exemplary embodiment of the present invention, as shown in FIG. 3, for detecting the magnitude of a beam current according to the magnitude of an input image signal, comparing the detected output signal with a reference signal, and outputting a corresponding signal. Unit 100; A correction signal generator 200 generating vertical and horizontal synchronization signals synchronized with a blank period of an image signal, outputting a horizontal parabola signal synchronized with a horizontal synchronous signal, and outputting a vertical parabola signal synchronized with a vertical synchronous signal; A variable gain amplifier (300) for adjusting the horizontal and vertical parabola signals with a gain according to the output signal of the correction discriminating unit (100), and outputting the sum of the horizontal and vertical parabola signals; An image processor 400 for demodulating and outputting an output signal of the variable gain amplifier 300; And an image output unit 500 that amplifies the output signal of the image processing unit 400 and outputs the amplified signal to the CRT.

The correction discrimination unit 100 includes a beam current detection unit 110 for detecting the magnitude of the beam current according to the magnitude of the input image signal; Comparing unit 120 for comparing the detected output signal with the reference signal and outputs the corresponding signal.

The correction signal generator 200 includes a synchronization signal generator 210 for generating vertical and horizontal synchronization signals synchronized with a blank period of an image signal; A horizontal parabolic signal generator 220 outputting a horizontal parabolic signal synchronized with the horizontal synchronous signal; The vertical parabola signal generator 230 outputs a vertical parabola signal synchronized with the vertical synchronization signal.

Looking at the operation of an embodiment of the present invention configured as described above are as follows.

First, for ease of understanding, it is assumed that the video signal is a 100% white level signal.

The brightness of the screen is determined according to the magnitude of the input image signal. When the image signal is input, the beam current detector 110 detects the magnitude of the beam current at that time.

At this time, the comparator 200 compares the detected voltage of the beam current detector 110 with a preset reference voltage and outputs a corresponding voltage. When the detected voltage is greater than the reference voltage, the comparator 200 outputs a difference signal proportional thereto. However, no output is made when the detected voltage is lower than the reference voltage.

The synchronization signal generator 210 is shown in FIGS. 5 (a) and 6 (d) in synchronization with the blank period of the video signal as shown in FIGS. 5 (a) and 6 (a). It generates horizontal and vertical synchronous signals.

At this time, the horizontal parabolic signal generation unit 220 outputs a horizontal parabolic signal in synchronization with the horizontal synchronization signal of the synchronization signal generation unit 210 as shown in FIG.

The vertical parabola signal generator 230 outputs a vertical parabola signal synchronized with the vertical synchronization signal of the synchronization signal generator 210 shown in FIG.

As such, the variable gain amplifier 300 receiving the detection voltage of the comparator 120 and the horizontal and vertical parabola signals outputs the input image signal by adding the horizontal and vertical parabola signals and amplifies the signal according to the detection voltage. do.

The video signal is then output as a corrected video signal as shown in Figs. 5 (c) and 6 (c).

As described above, the direct current (DC) level of the periphery is relatively higher than the center of the screen, so that the luminance levels of the center and the periphery are relatively different.

The image processor 400 receives the output signal of the variable gain amplifier 300 and demodulates the output signal. The image output unit 500 amplifies the demodulated signal and applies the demodulated signal to the CRT.

On the other hand, the reason why the synchronization signal synchronized with the blank period of the video signal is necessary is that the pedestal level serving as the black level reference is present in the blank period of the video signal.

The pedestal level is a DC voltage level that is used as a reference for making a composite video signal by mixing a video signal, a blanking signal, and a sync signal in a TV. The blanking signal is applied according to this level, and the sync signal is applied to the black level side. The amplitude is greater), and the video signal is applied to the back level (the amplitude).

When the pedestal level is changed, the black level reference is changed, so that the image processing unit 400 may have a low contrast or may be a screen indistinguishable from black.

Therefore, in order not to change the pedestal section from the original video signal, the synchronization signal generator 210 is required.

If the detection voltage is less than the reference voltage in the operation of the comparator 120, the output is not displayed. When the brightness of the peripheral part is corrected in a dark image below a specific level, the brightness of the center part is relatively lowered to prevent awkward screen. It is to.

Therefore, when there is no output of the comparator 120, the peripheral brightness correction is not performed.

On the contrary, when the detected voltage is greater than the reference voltage, the voltage proportional to the difference signal is output to harmonize the brightness of the entire screen by further compensating the brightness of the peripheral part in a bright screen over a certain level.

Therefore, when the beam current is greater than the reference voltage, that is, in a bright screen state, the output voltage of the comparator 120 is also increased. Accordingly, the variable gain amplifier 300 amplifies the gain of the horizontal and vertical parabolic signals by changing the gain even more.

As described in detail above, the present invention corrects an image signal with a parabola signal synchronized with a blank period of the image signal, detects the magnitude of the beam current, and changes the gain of the parabola signal according to the detected voltage, thereby correcting a bright screen. In large and dark screens, the correction can be made small so that the screen can be viewed with a uniform brightness.

Claims (3)

Correction means for detecting the magnitude of the beam current according to the magnitude of the input image signal, comparing the detected output signal with a reference signal, and outputting a corresponding signal; Correction signal generating means for generating vertical and horizontal synchronization signals synchronized with a blank period of the video signal, outputting a horizontal parabola signal synchronized with a horizontal synchronous signal, and outputting a vertical parabola signal synchronized with a vertical synchronous signal; Variable gain amplifying means for adjusting the horizontal and vertical parabolic signals with a gain in accordance with an output signal of the correction judging means, and outputting the sum of the horizontal and vertical parabola signals; Image processing means for demodulating and outputting the output signal of the variable gain amplifying means; And an image output means for amplifying an output signal of the image processing means and outputting the amplified output signal to the CRT. 2. The apparatus of claim 1, wherein the correction discriminating means comprises: beam current detecting means for detecting the magnitude of the beam current according to the magnitude of the input image signal; And a comparator means for comparing the detected output signal with a reference signal and outputting a corresponding signal. 2. The apparatus of claim 1, wherein the correction signal generating means comprises: synchronization signal generating means for generating vertical and horizontal synchronization signals synchronized with a blank period of the video signal; Horizontal parabolic signal generating means for outputting a horizontal parabolic signal synchronized with the horizontal synchronous signal; And a vertical parabolic signal generating means for outputting a vertical parabola signal synchronized with the vertical synchronous signal.